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Noise studies DESY + CERN TB overview

This report provides an overview of the noise studies conducted at DESY and CERN Test Beam. It includes the standard deviation for each channel pair in x and y directions, as well as the method and variables definition for noise analysis. The report also presents the results for different layers and PCBs, along with the impact of correlated noise on MC simulations.

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Noise studies DESY + CERN TB overview

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  1. Noise studiesDESY + CERN TB overview Anne-Marie Magnan Imperial College London CALICE-UK, Manchester - A.-M. Magnan -

  2. Standard deviation for each channel pairs in x direction High noise Standard deviation for each channel pairs in y direction Correct noise Method and Variables definition “NORMAL” channel “NOISY” channel Pedestal vs time Pedestal vs time • Will now look at <σ>, <σ1>and <σ2> per chip, and per PCB • And then average per PCB in function of run number (= time dependance) Channel 1 Channel 1 Channel 0 Channel 0 Difference between 2 channels Difference between 2 channels RMS = 8.44 RMS = 7.67 CALICE-UK, Manchester - A.-M. Magnan -

  3. Conclusion for DESY • Roughly stable noise, with some stable noisy layers (from 1 to 30) : • Layer 5 , PCB 8_C : ±3 ADC = ± 0.06 MIP correlated noise added to the standard 6 ADC = 0.12 MIP noise. • Layer 7 , PCB 4_C : ±3 ADC = ± 0.06 MIP correlated noise added to the standard 6 ADC = 0.12 MIP noise. • Layer 8 , PCB 5_C : ±6 ADC = ± 0.12 MIPcorrelated noise added to the standard 6 ADC = 0.12 MIP noise. • Layer 10 , PCB 12_C : ±1.5 ADC = ± 0.03 MIP correlated noise added to the standard 6 ADC = 0.12 MIP noise. • Added in digisim. Feedback welcome by the way !! CALICE-UK, Manchester - A.-M. Magnan -

  4. Results for CERN : August period • Relatively stable in time, a few noisy layers as well, same or different from DESY one’s : • Layer 2 , PCB 12_C : ±2.5 ADC = ± 0.05 MIP correlated noise added to the standard 6 ADC = 0.12 MIP noise. • Layer 3 , PCB 4_C : ±3 ADC = ± 0.06 MIP correlated noise added to the standard 6 ADC = 0.12 MIP noise. • Layer 15 , PCB 18_C : ±3 ADC = ± 0.06 MIP correlated noise added to the standard 6 ADC = 0.12 MIP noise. CALICE-UK, Manchester - A.-M. Magnan -

  5. Results for CERN : October period Ped vs Time, Run 300490, slot 17, FE 5 (PCB 4_C, layer 2), chip 0 • Confused !! And really unstable in time..... • 1st observation : more variations channel by channel • 2nd observation : more variations between chips • 3rd observation : the most important effect : pedestal unstabilities of up to 20-30 ADC counts  > 0.5 MIP nEvt (25/bin) CALICE-UK, Manchester - A.-M. Magnan -

  6. Results channel by channel CALICE-UK, Manchester - A.-M. Magnan -

  7. Average noise per run, over Aug and Oct data Layer 26 Layer 30 Layer 25 Layer 28 Layer 29 Layer 27 X-axis : run number (300XXX) Y-axis : noise (0-10) Layer 9 CALICE-UK, Manchester - A.-M. Magnan -

  8. Average noise per run, over Aug and Oct data (2) Layer 4 Layer 2 X-axis : run number (300XXX) Y-axis : noise (0-10) Layer 8 Layer 6 Layer 10 Layer12 Layer 14 Layer 16 CALICE-UK, Manchester - A.-M. Magnan -

  9. Average noise per run, over Aug and Oct data (3) Layer 18 Layer 20 X-axis : run number (300XXX) Y-axis : noise (0-10) (0-40) Layer 22 Layer 24 Layer 1 Layer3 Layer 5 Layer 7 CALICE-UK, Manchester - A.-M. Magnan -

  10. Average noise per run, over Aug and Oct data (4) Layer 11 X-axis : run number (300XXX) Y-axis : noise (0-10) (0-40) Layer 13 Layer 15 Layer 17 Layer19 Layer 21 Layer 23 CALICE-UK, Manchester - A.-M. Magnan -

  11. Already corrected by Goetz ?? • Goetz procedure as I understand it, currently in the Reco : Signal events 500 Pedestal events 1- substract pedestal previously calculated 2- Event by event : look at ADC values Pedestal per channel 3- Cut on S/N to discard signal cells 4- Calculate mean and RMS of the remaining events 5- iterate until the mean is stable and the RMS is ~6 ADC counts on the negative side.  This only works if there is enough channels without significant signal !!! CALICE-UK, Manchester - A.-M. Magnan -

  12. Preliminary conclusion • Error finally from this procedure, due to rounding apparently (need to be check !) ~4%MIP • Apply these 4%MIP remaining correlated noise to the MC, on top of the standard noise of ~6 ADC counts • Need to study precisely the impact on MC.... • ... And the real value in the data !!! Because if the correction is inducing that big an error, we should apply it only on the bad PCBs... It’s currently applied everywhere... • Preliminary digisim steering files : will soon be released in CVS calice repositery, with the correlated noise before Goetz’s corrections. To compare with actual reconstructed data files : need to test with or without adding a 4%MIP correlated noise everywhere instead of the values of the correlated noise put by default in the steering files ??!? • Note : digisim doesn’t release the position, as it’s not linked to the database.... Another good reason to have a common reconstruction code for DATA and MC ASAP !!!!!!!!!!!!!!!!! CALICE-UK, Manchester - A.-M. Magnan -

  13. MC impact of correlated noise CALICE-UK, Manchester - A.-M. Magnan -

  14. Layer 13 CALICE-UK, Manchester - A.-M. Magnan -

  15. Layer 25 CALICE-UK, Manchester - A.-M. Magnan -

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